RU2439820C1 - Radio modem - Google Patents

Abstract

FIELD: radio engineering.

SUBSTANCE: device comprises an analogue-digital converter (1), interfaces (2, 4, 14, 22, 27, 43, 46), a control unit (3), codecs (7, 51, 52, 53, 54, 55), antenna feeder units (5, 34), commutators (6, 9, 11, 33, 44), summators (8, 10, 41, 42), a packet device (12), a transmitting unit (13), frequency synthesisers (15, 21, 56, 47), registers (16, 17, 18, 19, 23, 29, 40, 49, 50), a generator of code sequences (20), units of cryptoprotection (24, 25, 38, 39), a clock pulse oscillator (26), shift registers (28, 57), an amplifying converter unit (30), a phased locked loop unit (31), a receiving unit (32), a unit of signal element identification (35), k comparison circuits (36₁ 36_k), a multiplexer (37), a digital to analogue converter (45), a comparator (48). In the device a packet is formed, transmitted and received, containing cryptographically protected information, using a combination code determined by the first and second pseudorandom numbers (PRN1 and PRN2) and synchrosequence, besides, every of two parts of the packet is modulated by different frequencies determined by the PRN2.

EFFECT: provision of safe mode of operation with self-recovery of a radio network with packet transfer of data consisting of mobile subscribers in case of passive enemy attacks.

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Description

The proposed device relates to the field of radio engineering and may find application in adaptive systems of special radio communications for transmitting data over a radio channel under the influence of a complex of intentional interference.

A software modem is known for using the characteristics of distortion due to group delay to determine the optimal symbol rate and carrier frequency for transmitting and receiving data, described in [1], in which, in various cases, the variance of distortion due to group delay is determined either directly or indirectly, as a correlation of amplitude distortion or as a correlation of a selected transmission predistortion filter defined in the ITU V.34 protocol.

A known digital modem for data transmission systems with phase-manipulated and amplitude-manipulated signals transmitted with one sideband (FM OBP and AFM OBP) and partially suppressed sideband (FM CBP and AFM CBP), described in [2], which eliminates fast fluctuations of the phase of the carrier oscillation based on the adaptive compensation method.

The disadvantage of the aforementioned devices is that they are designed to function only under conditions of natural interference and are not functional during active and passive attacks of the enemy [3, 12].

The closest in technical essence to the claimed is the device described in [4], taken as a prototype.

The functional diagram of the prototype device is shown in figure 1, where the following notation:

5 - antenna-feeder unit (AFB);

7 - codec (control unit);

13 - transmitting unit (BOP);

14 is a first interface;

43 - the second interface;

58 - LED indicator of work (SIR);

59 - galvanic isolation of power circuits (GICP).

The prototype device contains a codec, the first input-output of which is connected to the input-output of the first interface 14, the second input-output - with the input-output of the second interface 43, the third input-output - with the input-output of the SIR 58, and the fourth input-output - with the input-output of the PB 13, the second input-output of which is connected to the input-output of the AFB 5. The first output of the GICP 59 is connected to a single input of the codec 7, and the second output to a single input of the PB 13.

Block 14 is designed as an RS-232 interface.

The functional diagram of block 43 is made as shown in figure 2, where the following notation:

43.1 - optical isolation RS-485 (OI);

43.2 - RS-485 interface.

Block 43 contains an RS-485 43.2 interface, the input-output of which is connected to the first input-output of the OI 43.1, the second input-output of which is the input-output of the block 43.

Functional diagram of the codec is presented in figure 3, where the following notation:

7.1 - control microcontroller (UM);

7.2 - microcontroller power supply stabilizer (SPM).

Block 7 contains series-connected SPM 7.2, the input of which is the input of the codec 7, and UM 7.1, the four inputs and outputs of which are the corresponding inputs and outputs of the codec 7.

PB 13 is made as shown in figure 4, where the following notation:

13.1 - radio transceiver (RPP);

13.2 - power supply stabilizer of a radio transceiver (SPR).

PB 13 contains series-connected SPR 13.2, the input of which is the input of block 13, and RPP 13.1, two inputs and outputs of which are the corresponding inputs and outputs of the PB 13.

The operation of the prototype device is as follows.

The radio modem contains a printed circuit board on which the codec 7, AFB 5, SIR 58 and PB 13 is located. The data stream enters through the block 14 into the codec 7, which encodes this stream. The encoded data is transferred to the PB 13, where it is converted into a modulated radio frequency signal, which is transmitted to the receiver using the AFB 5. The operating modes are displayed in the SIR 58. In addition, the processed data is transmitted through block 43 to external devices. The power circuits of the radio modem are galvanically isolated from the external power supply unit GIUP 59.

Based on the description of the operation of the prototype device, we can conclude that it is not adapted to work in conditions of special communication. These conditions imply the functioning of the radio modem in the conditions of "information war", that is, the ability of the device to withstand unauthorized access to data passing through it. This ability is provided by the use of means of cryptographic information protection (CPSI) and pseudo-random tuning of the operating frequency (HFCH), and HHF and HFM should be used in networked environments. Therefore, in the prototype device, data encoding can only be understood as effective or noise-resistant encoding (and not as the use of cryptographic information protection) for the following reasons.

Modern communication networks are a combination of a large number of mobile subscribers (mobile modems) operating synchronously. The word "mobile" implies that any of the subscribers can temporarily leave network synchronism (disconnect; move beyond the network coverage area; etc.). In order to return to the network and continue exchanging data with other network subscribers, he needs to restore synchronous operation mode with them. The restoration of synchronism is understood primarily as the restoration of synchronism in the cryptographic information protection (generation of the same pseudorandom numbers) and frequency hopping (data exchange at the same frequencies). This can be achieved only by introducing special algorithms in the radio modem to stop the overall synchronous operation of the network and exchange some information with all subscribers of the network (including the subscriber who wants to enter the network) in order to restart the network based on this information.

Thus, the disadvantage of the prototype device is the inability to protect data from unauthorized access.

The claimed invention solves the problem of introducing the ability of a radio modem to provide a secure mode of operation for communication networks consisting of mobile subscribers.

The technical result achieved by using the invention is the provision of a protected mode of operation with the self-healing of a packet data network (RAPD) radio network consisting of mobile subscribers during passive enemy attacks.

To solve the problem, a radio modem containing the first codec, third and sixth interfaces, a transmitting unit connected to the first antenna-feeder unit, the output of which is the output of the device, according to the invention, the first interface, an analog-to-digital converter (ADC) and the first are connected in series a switch whose output is connected to the first input of the first codec; connected in series are the first adder, the first input of which is connected to the output of the first codec, the second switch, the second adder, the third switch and the packetizer, the output of which is connected to the first input of the transmitting unit; connected in series to a second AFB, the input of which is the input of the device, an amplifier-converter unit (UPB), a phase-locked loop (BFA), a receiving unit, a fourth switch, a fourth adder, a third adder, a sixth codec, a fifth switch, a digital-to-analog converter (DAC), and seventh interface; the fourth interface, the fifth register, the second register, the first register and the first cryptographic protection unit (BKZ) are connected in series, the output of which is connected to the second input of the first register, the second output of which is connected to the second input of the second register; the fifth interface, the first shift register, the second BKZ, the third register and the fourth register, the first output of which is connected to the second input of the third register, the second output of which is connected to the second input of the second cryptographic protection unit; sequentially connected to the second shift register, the first input of which is connected to the second output of the fifth interface, the third BKZ and the sixth register; in addition, a control unit, a clock generator, a code sequence generator, a fourth BKZ, a signal element identification unit (BECS), a multiplexer, a comparator, k comparison circuits, as well as the first, second, third and fourth frequency synthesizers were introduced; second interface; second, third, fourth and fifth codecs; seventh, eighth and ninth registers; wherein the third output of the first register is connected to the second input of the first adder; the third output of the third register is connected to the second input of the second adder; the second output of the second register is connected to the first input of the second codec, the output of which is connected to the second input of the second switch; the second output of the fourth register is connected to the first inputs of the first and second frequency synthesizers and the third codec, the output of which is connected to the second input of the third switch; the second output of the fourth switch is connected to the first input of the fifth codec, the output of which is connected to the first input of the ninth register, the output of which is connected to the second input of the seventh register, the first output of which is connected to the second input of the fourth BKZ; the second output of the seventh register is connected to the second input of the third adder; the third output of the fourth switch is connected to the first input of the fourth codec, the output of which is connected to the first input of the eighth register, the output of which is connected to the first inputs of the third and fourth frequency synthesizers and the second input of the sixth register, the first output of which is connected to the second input of the third BKZ; the second output of the sixth register is connected to the second input of the fourth adder; the second output of the second AFB is connected to the first signal input of the BOES, the output of which is connected to the signal inputs of k comparison circuits, the outputs of which are connected to the corresponding k signal inputs of the comparator and multiplexer; the output of the comparator is connected to the address input of the multiplexer, the output of which is connected to the second input of the BFA; in addition, the output of the first shift register is connected to the second input of the first BKZ, and the output of the second shift register is connected to the first input of the fourth BKZ, the output of which is connected to the first input of the seventh register; the group of outputs of the second interface is connected via a bus to the group of information inputs of the control unit, the first group of outputs of which is connected to the groups of control inputs of the first switch, the first, second and third codecs, the second and third switches, and the second group of outputs of the control unit is connected to the groups of control inputs by the bus the fourth and fifth switches, as well as the fourth, fifth and sixth codecs; the output of the third frequency synthesizer is connected to the second input of the UPB, and the output of the fourth frequency synthesizer is connected to the second input of the BOES; the output of the third interface is connected to the third input of the first switch; the output of the code sequence generator is connected to the second input of the packetizer, the second output of the fifth switch is connected to the sixth interface; the second output of the second switch is connected to the fourth input of the third switch; the second output of the fourth interface is connected to the second input of the fourth register; the output of the first frequency synthesizer is connected to the second input of the transmitting unit, and the output of the second frequency synthesizer is connected to the third input of the transmitting unit; the output of the clock generator is connected to the clock inputs of the control unit, comparator, transmitting and receiving blocks, BFA, ADC, DAC, BOES, packetizer, multiplexer, code sequence generator, each of six codecs, each of six switches, each of four adders, each of nine registers, each of two shift registers, each of four frequency synthesizers, each of four cryptographic protection blocks, each of k comparison schemes.

Functional diagram of the inventive device is shown in figure 5, where the following notation:

1 - analog-to-digital Converter (ADC);

2 - the first interface (I1);

3 - control unit (UB);

4 - second interface (I2);

5 - the first antenna-feeder unit (AFB1);

6 - the first switch (K1);

7 - the first codec;

8 - the first adder (C1);

9 - the second switch (K2);

10 - second adder (C2);

11 - the third switch (K3);

12 - packer;

13 - transmitting unit (BOP);

14 - third interface (I3);

15 - the first frequency synthesizer (MF1);

16 - the first register (P1);

17 - the second register (P2);

18 - the third register (P3);

19 - the fourth register (P4);

20 - code sequence generator (GKP);

21 - the second frequency synthesizer (MF2);

22 - the fourth interface (I4);

23 - fifth register (P5);

24 - the first block of cryptographic protection (BKZ1);

25 - the second block of cryptographic protection (BKZ2);

26 - clock generator (GTI);

27 - fifth interface (I5);

28 - the first shift register (PC1);

29 - sixth register (P6);

30 - amplifier-conversion unit (UPB);

31 - phase-locked loop (BFA);

32 - receiving unit (PRB);

33 - the fourth switch (K4);

34 - the second antenna-feeder unit (AFB2);

35 - block identification of the signal element (BOES);

36 ₁ ... 36 _k - k comparison schemes (SS);

37 - multiplexer;

38 - the third block of cryptographic protection (BKZ3);

39 - the fourth block of cryptographic protection (BKZ4);

40 - seventh register (P7);

41 - third adder (C3);

42 - fourth adder (C4);

43 - the sixth interface (I6);

44 - fifth switch (K5);

45 - digital-to-analog converter (DAC);

46 - seventh interface (I7);

47 - the fourth frequency synthesizer (MF4);

48 - a comparator;

49 - eighth register (P8);

50 - ninth register (P9);

51 - the second codec;

52 - the third codec;

53 - the fourth codec;

54 - the fifth codec;

55 - the sixth codec;

56 - the third frequency synthesizer (MF3);

57 - the second shift register (PC2).

The inventive device comprises serially connected I1 2, ADC 1, K1 6, the first codec 7, C1 8, K2 9, C2 10, K3 11, packetizer 12, PB 13 and AFB1 5, the output of which is the output of the device; connected in series AFB2 34, the input of which is the input of the device, UPB 30, BFA 31, PRB 32, K4 33, C4 42, C3 41, sixth codec 55, K5 44, DAC 45 and I7 46; serially connected I4 22, P5 23, P2 17, P1 16 and BKZ1 24, the output of which is connected to the second input P1 16, the second output of which is connected to the second input P2 17; serially connected I5 27, PC1 28, BKZ2 25, P3 18 and P4 19, the first output of which is connected to the second input P3 18, the second output of which is connected to the second input BKZ2 25. The second output I5 27 is connected to serially connected PC2 57, BKZ3 38 and P6 29.

In addition, the output of PC1 28 is connected to the second input of BKZ1 24, and the output of PC2 57 to the first input of BKZ4 39, the output of which is connected to the first input of P7 40.

The third output P1 16 is connected to the second input C1 8; the third output P3 18 is connected to the second input C2 10; the second output P2 17 is connected to the first input of the second codec 51, the output of which is connected to the second input K2 9; the second output P4 19 is connected to the first inputs of the midrange 15, midrange 21 and the third codec 52, the output of which is connected to the second input K3 11.

The second output K4 33 is connected to the first input of the fifth codec 54, the output of which is connected to the first input P9 50, the output of which is connected to the second input P7 40, the first output of which is connected to the second input BKZ4 39.

The second output P7 40 is connected to the second input C3 41. The third output K4 33 is connected to the first input of the fourth codec 53, the output of which is connected to the first input P8 49, the output of which is connected to the first inputs MF3 56, MF4 47 and the second input P6 29, the first the output of which is connected to the second input of BKZ3 38. The second output of P6 29 is connected to the second input of C4 42.

The second output of AFB2 34 is connected to the first signal input of BOES 35, the output of which is connected to the signal inputs k of comparison circuits (CC) 36 ₁ -36 _k , the outputs of which are connected to the corresponding k signal inputs of comparator 48 and multiplexer 37. The output of comparator 48 is connected to the address input of the multiplexer 37, the output of which is connected to the second input of the BFA 31.

The group of outputs I2 4 is connected via a bus to the group of information inputs of UB 3, the first group of outputs of which is connected by bus to the groups of control inputs K1 6, the first codec 7, the second codec 51, the third codec 52, K2 9, K3 11, and the second group of outputs UB 3 the bus is connected to the groups of control inputs K4 33, K5 44, the fourth codec 53, the fifth codec 54 and the sixth codec 55.

The output MF3 56 is connected to the second input of the UPB 30, and the output MF4 47 is connected to the second input of the BOES 35. The output of I3 14 is connected to the third input of K1 6. The output of the HCP 20 is connected to the second input of the packer 12. The second output of K5 44 is connected to I6 43.

The second output K2 9 is connected to the fourth input K3 11. The second output И4 22 is connected to the second input Р4 19. The output СЧ1 15 is connected to the second input of ПБ 13, and the output СЧ2 21 is connected to the third input of ПБ 13.

The output of the GTI 26 is connected to the clock inputs of the blocks 1, 3, 6-13, 15-21, 23-25, 28, 29, 31-33, 35, 37-42, 44, 45, 47-57, as well as the clock inputs k comparison schemes 36 ₁ -36 _k .

The device operates as follows. On the transmitting side, a stream of analog information flows through I1 2 to ADC 1, where it is digitized. The resulting digital data stream, like the digital data stream coming through I3 14, through K1 6 enters the first codec 7, which encodes this stream based on the control signal from UB 3. At the same time, K1 6 passes or the data stream from I3 14 , or the data stream from the ADC 1, based on the control signal from UB 3.

Coded data comes in blocks of y ₁ bit in C1 8, where they are added to the contents of P1 16 (size y ₁ bit), which is a pseudo-random value. The data encrypted in C1 8 is received in blocks of y ₂ bits through K2 9, based on the control signal from UB 3, in C2 10, where they are added to the contents of P3 18 (size y ₂ bits), which is a pseudo-random value. The data encrypted a second time in C2 10 is transmitted via K3 11, based on the control signal from UB 3, to the packetizer 12, where they are combined with the sync sequence coming from the HCP 20.

A packet formed in a packetizer 12 and consisting of two parts — encrypted information and a synchronization sequence — arrives at PB 13, where it is converted to a modulated radio frequency signal, which is transmitted to the receiver using AFB1 5. Each of the two parts of the packet is modulated by different frequencies supplied to the packetizer 13 from MF1 15 and MF2 21. The numbers of these frequencies (up to x ₂ bits each) arrive at MF1 15 and MF2 21 from P4 19.

Two digital constants of size x ₁ and x ₂ bits, respectively, pass through I4 22 to P5 23 and P4 19. These constants must be individual for each network radio modem and can, for example, be some functions of the network address of the MS that includes this radio modem. The constant from P5 23 is rewritten in P2 17. Thus, the initial loading of blocks 17 and 19 is carried out, having dimensions of x ₁ and x ₂ bits, respectively.

Blocks 16 and 18 should be sized respectively y ₁ ≥x ₁ and y ₂ ≥x ₂ bits. Therefore, the values of blocks 17 and 19 must "multiply" into the values of blocks 16 and 18 according to the functions f ₁ and f ₂ . "Reproduction" may consist, for example, in a simple duplication of certain bits. Thus, y ₁ = f ₁ (x ₁ ), and y ₂ = f ₂ (x ₂ ).

At initial loading, the values of P1 16 and P3 18 are not yet a pseudo-random number, but are only the initial (zero) state of blocks 24 and 25, respectively. Therefore, to generate pseudorandom numbers used to sum with the incoming data in C1 8 and C2 10, the value of P1 16 goes to BKZ1 24, and the value of P3 8 to BKZ2 25. In blocks 24 and 25, pseudorandom numbers are generated by cryptographic algorithms g ₁ and g _2, respectively. The development is based on the value of PC1 28, loaded into BKZ1 24 and BKZ2 25 and supplied to PC1 28 through I5 27. This value is a constant of size z bits, which is the key of the cryptographic algorithms g ₁ and g ₂ . If the cryptographic algorithm consists of several cycles, after each cycle in block 28 there is a shift by d bits.

The obtained pseudo-random numbers are loaded from BKZ1 24 to P1 16 and from BKZ2 25 to P3 18, respectively, and the resulting values of P1 16 and P2 18 are used to sum with the incoming data in C1 8 and C2 10. Thus, the speed of block 24 should be so as to generate a pseudo-random number before entering another block of data in block 8, and the speed of block 25 to generate a pseudo-random number before entering into block 10 of the next data block.

The presence of encoders in the modem ensures the confidentiality of the information circulating in the network. However, to maintain the modem’s synchronization on the transmitting and receiving sides, instead of transmitting encrypted data according to the main algorithm (described above), every T seconds, the following procedure is provided:

1) certain bits (in the amount of x ₁ ) from the current value of block 16 are loaded into block 17;

1) certain bits (in the amount of x ₂ ) from the current value of block 18 are loaded into block 19;

3) the value of block 17, called the first current time stamp (TBM1), enters the second codec 51, which encodes TBM1 based on the control signal from UB 3;

4) based on the control signal from UB 3, the encoded TBM1 through K2 9 enters K3 11;

5) based on the control signal from UB 3 through K3 11, the encoded TBM1 enters the packetizer 12;

6) the value of block 19, called the second current time stamp (TBM2), enters the third codec 52, which encodes TBM2 based on the control signal from UB 3;

7) based on the control signal from UB 3 through K3 11, the encoded TBM2 enters the packetizer 12;

8) in the packetizer 12 there is a combination of TBM1 and TBM2 with the sync sequence coming from GKP 20;

9) the packet formed in the packetizer 12 and consisting of three parts: the sync sequence, TBM1 and TBM2, enters the PB 13, where it is converted into a modulated radio frequency signal, which is transmitted to the recipient using AFB1 5;

10) each of the three parts of the packet is modulated by different frequencies entering the packetizer 13 from MF1 15 and MF2 21, and the numbers of these frequencies (up to x ₂ bits each) arrive at MF1 15 and MF2 21 from P4 19;

11) points 9, 10 are repeated m times.

After completion of the procedure, consisting of paragraphs 1-11, the values of blocks 17 and 19 should "multiply" in the values of blocks 16 and 18 according to the functions f ₁ and f ₂ . After that, the work of the transmitting part of the device corresponds to the work of transmitting encrypted data according to the main algorithm.

At the receiving end, the input signal, which is a mixture of the useful signal and interference, is received by AFB2 34, where it is divided into service and information components.

The part of the input signal containing the service component from the second output of AFB2 34 is fed to the first signal input of BOES 35. The sequence of random elements of the mixture is converted into BOES 35 into a random sequence of decisions about the symbols corresponding to the received elements of the signal using the receive frequency received at the output of MF4 47 based on the value supplied from the output of P8 49. This sequence of decisions on symbols in the general case due to interference does not coincide with any of the sequences of symbols of the elements The ones that were used on the transmitting side in the formation of sync sequences in HCP 20. In BOES 35, the mixture of the signal element and the noise is processed optimally, and a sequence of decisions about which sync sequence element (logical “0” or logical “1”) is output at its output. The obtained sequence of decisions about symbols is compared element by element with the codes of the expected sync sequences in the corresponding CC 36 ₁ -36 _k .

The comparison results from the outputs of the CC 36 ₁ -36 _k are fed to the comparator 48, which sets the maximum of k input values. This maximum determines the control signal for the multiplexer 37.

The comparison results from the outputs of the CC 36 ₁ -36 _k are also provided to the corresponding signal inputs of the multiplexer 37, in which, based on the control signal coming from the comparator 48, one of the k inputs is selected, the signal from which is fed to the second through the multiplexer 37 signal input BFA 31.

Another part of the input signal containing the information component is fed to the first input of the UPB 30, in which the spectrum of the input signal is shifted to the intermediate frequency at which the main signal processing is performed, followed by amplification of the intermediate frequency signal.

The conversion to the reception frequency occurs in the UPB 30 based on the frequency coming from the output of MF3 56 based on the value supplied from the output of P8 49.

The signal from the output of the UPB 30 is fed to the first signal input of the BFA 31, in which the exact phase adjustment of the information component and the clock sequence based on the service component occurs. The signal from the output of the BFA 31 is fed to the signal input of the PRB 32, where it is demodulated.

From the output of block 32, the encrypted data is received in blocks of y ₂ bits through K4 33, based on the control signal from UB 3, to C4 42, where they are added to the contents of P6 29 (size y ₂ bits), which is a pseudo-random value. After block 42, the encrypted data arrives in blocks of y ₁ bit in C3 41, where they are added to the contents of P7 40 (size y ₁ bit), which is also a pseudo-random value.

To generate pseudorandom numbers used for summing with encrypted data in C4 42 and C3 41, the value of P6 29 goes to BKZ3 38, and the value of P7 40 goes to BKZ4 39. In blocks 38 and 39, pseudorandom numbers are generated using cryptographic algorithms g ₂ and g _1, respectively. The development is based on the value of PC2 57, loaded into BKZ3 38 and BKZ4 39 and supplied to PC2 57 through I5 27. This value is a constant of size z bits, which is the key of the cryptographic algorithms g ₁ and g ₂ . If the cryptographic algorithm consists of several cycles, after each cycle in block 57, a shift by d bits occurs.

The decrypted data stream from the output C3 41 is received in the sixth codec 55, which decodes this stream on the basis of the control signal from UB 3. From the output of the sixth codec 55 through K5 44, on the basis of the control signal from UB 3, the stream is sent to external devices or via 43, or, after conversion to an analog signal in the DAC 45, through block 46.

Based on the described operation algorithm, it follows that error-free decoding of data on the receiving side depends on the state of P6 29 and P7 40. To preserve the synchronism of the modem on the transmitting and receiving sides, instead of receiving encrypted data according to the main algorithm (described above), every T seconds is received two digital constants of size x ₁ and x ₂ bits, respectively. The constants, based on the control signal from UB 3, pass through K4 33 to the fifth codec 54 and the fourth codec 53, respectively. The constants decoded in the fifth 54 and fourth 53 codecs, based on the control signal from UB 3, are recorded in P9 50 and P8 49, respectively.

Thus, the initial loading of blocks 50 and 49 is carried out, having dimensions of x ₁ and x ₂ bits, respectively.

Blocks 40 and 29 are respectively y ₁ ≥x ₁ and y ₂ ≥x ₂ bits. Therefore, the values of blocks 50 and 49 must be converted to the values of blocks 40 and 29 according to the functions f ₁ and f ₂ , which are identical on the receiving and transmitting sides. That is, y ₁ = f ₁ (x ₁ ), ay ₂ = f ₂ (x ₂ ).

UB 3 controls the operation of blocks 6, 7, 9, 11, 33, 44, 51-55 based on the control program received through I2 4.

From the GTI 26 output to blocks 1, 3, 35, 44, 45, 6-13, 15-21, 23-25, 28, 29, 31-33, 37-42, 47-57, as well as to SS 36 ₁ -36 _k clock pulses are supplied, which determine the beginning of each microoperation, as a result of which synchronization of the operation of the device as a whole is ensured.

BPA 31 can be implemented in the form of schemes for linking the clock signal to the bit intervals of the received data [5, Chapter 9]. BOES 35 can be implemented as a decisive device [6, Chapter 7.4]. SS 36 ₁ -36 _k can be implemented in the form of discrete matched filters [6, chapter 7.4-7.5].

PB 13 and PRB 32 can be implemented as processors of the Motorola DSP56800 family [7, pp. 1-11, chapter 5]. Blocks 24, 25, 38, 39 can be implemented as any of the block or stream ciphers described in [3].

MF can be implemented as [9, chapter 3.2], UPB - as [9, chapter 2]. The interface can be implemented as any of the standard joints: C1-FL, RS-232, USB, Ethernet IEEE 802.3, Ethernet IEEE 802.11 a / g, Ethernet IEEE 802.16, optical channel.

HCP can be implemented as a generator of M-sequences [6, Chapter 4]. Blocks 6, 9, 11 can be implemented as multiplexers, and 33, 44 as demultiplexers, where the signal coming from UB 3 acts as an address code [11].

The packetizer and codecs can be implemented, for example, as digital signal processors described in [10, Chapter 9], including as a set of AD20msp430, containing two processors responsible for the formation of packets of the data transfer protocol, and performing the functions of speech and channel coding.

UB 3 can be implemented, for example, as a processor based on the Motorola SC140 Star * Core core [7], which contains a program control device (UPM), including a five-stage conveyor. The SC140 core has sixteen 40-bit universal data registers and twenty-seven 32-bit address registers, which can contain values and addresses of control signals for blocks 6, 7, 9, 11, 33, 44, 51-55. The value of the data register, which contains the number of the used codec, goes to blocks 7, 51-55, where, based on this number, encoding and decoding takes place. The value of the data register, which contains the number of the type of information used (digital or analog), is sent to block 6, which opens or closes the corresponding input. Values of data registers that determine the current state of the process of transmitting and receiving (transmitting or receiving a timestamp or transmitting or receiving data) are received (according to the SC140 program controller, which selects commands and executes cycles) to blocks 9, 11, 33, 44, which open or close the corresponding entrances.

The functioning algorithm of UB 3 is shown in Fig.6.

The values contained in blocks 3.4.1, 3.4.2, 3.6.1, 3.6.2, 3.7.1-3.7.α, as well as the control program of the PMU 3.2 are loaded into UB 3 using interface 4.

The operation of UB 3 begins with the start of the counter 3.1, on the basis of the signals of which UUP 3.2 provides control signals to the multiplexing units:

- 3.3, as a result of which it is determined which of the values contained in blocks 3.4.1 or 3.4.2 is output to UB 3 on blocks 9, 11, 33, 44;

- 3.5, as a result of which it is determined which of the values contained in blocks 3.6.1 or 3.6.2 is issued to the output of UB 3 to block 6;

- 3.8, as a result of which it is determined which of the values contained in blocks 3.7.1-3.7.α is output to UB 3 on blocks 7, 51-55.

Thus, the introduction of new blocks and connections in the proposed device allows the subscribers who leave the general synchronous network operation mode to enter the network back, which allows the radio modem to be used in special communication in conditions of unauthorized access from the enemy. In addition, the presence of several AFB and BKZ allows the radio modem to conduct not one but more communication sessions (for example, to provide communication as a mobile access point [8] between different subnets or to act as a relay).

Information sources

1. RF patent for the invention No. 2155454 "Device, method and software modem for using the characteristics of distortion due to group delay to determine the symbol rate and carrier frequency for data transfer", J.L. Moran III, S. Verma, V. L. Brown, 1997.

2. RF patent for the invention No. 2218666 “Digital modem”, Agapova VN, Aleksandrov SV, Bochkov VK, Zakharenkov V.E., Kashlov VV, Kiryukhin MS, Kolchugin A.I., Kotlov V.F., Lavrov G.I., Lysikov A.V., Mironov N.P., Prokhorov A.D., Sultanov B.V., Funtikov V.A., Shutov S. L., 2001.

3. Schneier B. Applied cryptography. Protocols, algorithms, source codes in the C language. - M.: Publishing. TRIUMPH, 2002.

4. RF patent for utility model No. 59918 "Radio modem", 2006, Lipsky RN, Shkuro Yu.V.

5. S.N. Sukhman, A.V. Bernov, B.V. Shevkoplyas. Synchronization in telecommunication systems. Analysis of engineering solutions. - M .: Eco-Trends, 2003.

6. Pestryakov VB Noise-like signals in information transmission systems. M., Soviet Radio, 1973

7. Technical support for digital signal processing. Directory. Kupriyanov M.S., Matyushkin B.D., Ivanova V.E., Matvienko N.I., Usov D.Yu. - SPb. The Fort, 2000.

8. P. Roshan, J. Lieri. The basics of building wireless LAN standard 802.11. Per. from English - M.: Williams Publishing House, 2004.

9. Radio receivers, ed. L.G. Barulina. - M., Radio and Communications, 1984

10. W. Kester. Digital signal processing. Analog Devices 1999

11. A.G. Alekseenko, I.I. Shagurin. Microcircuitry, 1990

12. Borisov V.I. and others. Interference immunity of radio communication systems with the expansion of the spectrum of signals by the method of pseudo-random tuning of the operating frequency. - M .: Radio and communications, 2000.

Claims (1)

A radio modem containing the first codec, third and sixth interfaces and a transmitting unit connected to the first antenna-feeder unit (AFB), the output of which is the output of the device, characterized in that the first interface, the analog-to-digital converter (ADC) and the first are connected in series a switch whose output is connected to the first input of the first codec; connected in series are the first adder, the first input of which is connected to the output of the first codec, the second switch, the second adder, the third switch and the packetizer, the output of which is connected to the first input of the transmitting unit; connected in series to a second AFB, the input of which is the input of the device, an amplifier-converter unit (UPB), a phase-locked loop (BFA), a receiving unit, a fourth switch, a fourth adder, a third adder, a sixth codec, a fifth switch, a digital-to-analog converter (DAC), and seventh interface; the fourth interface, the fifth register, the second register, the first register and the first cryptographic protection unit (BKZ) are connected in series, the output of which is connected to the second input of the first register, the second output of which is connected to the second input of the second register; the fifth interface, the first shift register, the second BKZ, the third register and the fourth register, the first output of which is connected to the second input of the third register, the second output of which is connected to the second input of the second cryptographic protection unit; sequentially connected to the second shift register, the first input of which is connected to the second output of the fifth interface, the third BKZ and the sixth register; in addition, a control unit, a clock generator, a code sequence generator, a fourth BKZ, a signal element identification unit (BECS), a multiplexer, a comparator, k comparison circuits, as well as the first, second, third and fourth frequency synthesizers were introduced; second interface; second, third, fourth and fifth codecs; seventh, eighth and ninth registers; wherein the third output of the first register is connected to the second input of the first adder; the third output of the third register is connected to the second input of the second adder; the second output of the second register is connected to the first input of the second codec, the output of which is connected to the second input of the second switch; the second output of the fourth register is connected to the first inputs of the first and second frequency synthesizers and the third codec, the output of which is connected to the second input of the third switch; the second output of the fourth switch is connected to the first input of the fifth codec, the output of which is connected to the first input of the ninth register, the output of which is connected to the second input of the seventh register, the first output of which is connected to the second input of the fourth BKZ; the second output of the seventh register is connected to the second input of the third adder; the third output of the fourth switch is connected to the first input of the fourth codec, the output of which is connected to the first input of the eighth register, the output of which is connected to the first inputs of the third and fourth frequency synthesizers and the second input of the sixth register, the first output of which is connected to the second input of the third BKZ; the second output of the sixth register is connected to the second input of the fourth adder; the second output of the second AFB is connected to the first signal input of the BOES, the output of which is connected to the signal inputs of k comparison circuits, the outputs of which are connected to the corresponding k signal inputs of the comparator and multiplexer; the output of the comparator is connected to the address input of the multiplexer, the output of which is connected to the second input of the BFA; in addition, the output of the first shift register is connected to the second input of the first BKZ, and the output of the second shift register is connected to the first input of the fourth BKZ, the output of which is connected to the first input of the seventh register; the group of outputs of the second interface is connected via a bus to the group of information inputs of the control unit, the first group of outputs of which is connected to the groups of control inputs of the first switch, the first, second and third codecs, the second and third switches, and the second group of outputs of the control unit is connected to the groups of control inputs by the bus the fourth and fifth switches, as well as the fourth, fifth and sixth codecs; the output of the third frequency synthesizer is connected to the second input of the UPB, and the output of the fourth frequency synthesizer is connected to the second input of the BOES; the output of the third interface is connected to the third input of the first switch; the output of the code sequence generator is connected to the second input of the packetizer, the second output of the fifth switch is connected to the sixth interface; the second output of the second switch is connected to the fourth input of the third switch; the second output of the fourth interface is connected to the second input of the fourth register; the output of the first frequency synthesizer is connected to the second input of the transmitting unit, and the output of the second frequency synthesizer is connected to the third input of the transmitting unit; the output of the clock generator is connected to the clock inputs of the control unit, comparator, transmitting and receiving blocks, BFA, ADC, DAC, BOES, packetizer, multiplexer, code sequence generator, each of six codecs, each of six switches, each of four adders, each of nine registers, each of two shift registers, each of four frequency synthesizers, each of four cryptographic protection blocks, each of k comparison schemes.

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